ORIGINAL PAPER

Carnivores as zoonotic parasite reservoirs in ancient times:
the case of the Epullán Chica archaeological cave (Late Holocene,
northwestern Patagonia, Argentina)

María Ornela Beltrame1,2 & Agustín Bellusci1 & Fernando Julián Fernández2,3 &

Norma Haydée Sardella1,2

Received: 15 April 2016 /Accepted: 26 September 2016
# Springer-Verlag Berlin Heidelberg 2016

Abstract Zoonoses are currently considered as one of the
most important threats for Public Health worldwide.
Numerous zoonoses known today have occurred since antiq-
uity. Carnivores act as definitive hosts for many intestinal
parasites; some of them are responsible for several zoonotic
diseases. The aim of this work was to study the parasite re-
mains found in coprolites assigned to carnivores from the
archaeological site Epullán Chica (ECh) and to discuss the
results from a zoonotic point of view. ECh is located in north-
western Patagonia, Argentina and was occupied since the end
of the Late Holocene (∼2200 years B.P.). Nine coprolites were
examined for parasites. Samples were processed by rehydra-
tion in a 0.5 %water solution of trissodium phosphate, follow-
ed by homogenization, filtered and processed by spontaneous
sedimentation. The macroscopic remains were separated and
dried at room temperature and were examined for diet analy-
sis. Six out of 9 coprolites examined were positive for para-
sites. Representatives of at least 10 parasite taxa were regis-
tered. Results are in line with the reconstruction of the scenar-
io of zoonoses in the past and the diseases that the human
populations and animals from Patagonia could be exposed.
The present study provides the first palaeoparasitological

report of carnivore coprolites recovered from the archaeolog-
ical site Ech and reflects contamination of the cave used by
hunter-gatherers with different parasites causative of zoonotic
diseases.

Keywords Palaeoparasitology . Patagonia . Carnivores .

Zoonoses

Introduction

Zoonoses are defined as any disease or infection that is natu-
rally transmissible from vertebrate or invertebrate animals to
humans and vice versa. Zoonoses are currently considered as
one of the most important threats for Public Health worldwide.
Viruses, parasites, bacteria and fungi can cause zoonotic in-
fections (Bueno-Marí et al. 2015). Numerous zoonoses known
today have occurred since antiquity.

Palaeoparasitology is the study of parasite remains from
archaeological and palaeontological sites (Ferreira 2014), fo-
cussed on the knowledge of parasite-induced illness of
humans in the past and on the palaeoecological knowledge
of the environment, ecology, settlement, diet, hygiene and
health in the antiquity (Reinhard 1992). Previous
palaeoparasitological studies on South American ancient pop-
ulations have shown the presence of the zoonotic helminths
Echinostoma sp., Paragonimus sp., Diphyllobothrium spp.,
Capillaria spp., Trichostrongylus sp. and Acanthocephala
(Sianto et al. 2009).

Carnivores act as definitive hosts for many intestinal para-
sites; some of them are responsible for several zoonotic dis-
eases such as paragonimiasis, sarcocystosis, toxoplasmosis
and cysticercosis (Jay 1996, Acha and Szyfres 2003).
Current diversity of South American terrestrial carnivores is
relatively high, with 40 out of 245 species of the order

* María Ornela Beltrame
ornelabeltrame@conicet.gov.ar

1 Laboratorio de Paleoparasitología y Arqueología Contextual,
Departamento de Biología, Facultad de Ciencias Exactas y Naturales,
Universidad Nacional de Mar del Plata, Funes 3250, 7600 Mar del
Plata, Buenos Aires, Argentina

2 Consejo Nacional de Investigaciones Científicas y Técnicas
(CONICET), Buenos Aires, Argentina

3 Cátedra de Anatomía Comparada, Facultad de Ciencias Naturales y
Museo, Universidad Nacional de La Plata, calle 64 s/n (entre diag.
113 y calle 120), 1900 La Plata, Buenos Aires, Argentina

Archaeol Anthropol Sci
DOI 10.1007/s12520-016-0399-8

http://crossmark.crossref.org/dialog/?doi=10.1007/s12520-016-0399-8&domain=pdf


Carnivora (Hunter 2011). The palaeontological record ex-
hibits that a rich diversity of carnivores also inhabited South
America in the past (e.g. Soibelzon and Prevosti 2007).

From ancient times, a close interaction between humans
and carnivores was present. This interaction may have
favoured the transmission of zoonotic parasitic diseases. The
study of carnivore parasites can improve the knowledge of
human zoonotic parasitic diseases in the past.

The archaeological site Epullán Grande cave is located in
the middle Limay River basin (northwestern Patagonia,
Argentina) and yielded remains from ca. 10,000 years B.P.
(before present) (Crivelli Montero et al. 1996). About 100 m
east from this cave is located a smaller archaeological cave
site, Epullán Chica (ECh), with a rich zooarchaeological re-
cord, occupied since the end of the Late Holocene (Fernández
et al. 2016). The zooarchaeological material present in both
caves evidences the interaction between hunter-gatherers and
animals from Pleistocene-Holocene transition to historical
times.

The aim of this work was to study the parasite remains
found in coprolites assigned to carnivores from the archaeo-
logical site Epullán Chica and to discuss the results from a
zoonotic point of view.

Material and methods

The archaeological site named Epullán Chica (ECh) is a cave
located at the southern of Neuquén Province, Argentina, 5 km
north of the Limay river valley (40° 23′ 10″ S, 70° 11′ 44″W,
680m) (Fig. 1). It is 5 mwide at the mouth and 3.5 m long and
covers 11 m2. Maximum depth of the fill was 1.40 m. The

archaeological sequence was dated around 2220 ± 50 years
14C B.P. (from a charcoal sample recovered from the deeper
layers) to the twentieth century (from a metal knife collected
from the upper layers). ECh is located in the Monte-Patagonia
ecotone of the three major vegetation units that occur in
Patagonia: forest, Patagonian steppe and Monte desert. The
annual precipitation is around 300 mm. Archaeological mate-
rials were recovered, including lithic artefacts, plant remains,
owl pellets, freshwater mollusc shells (Diplodon chilensis),
feathers of Cyanoliseus patagonus (burrowing parakeet),
bones and egg shell fragments of Rheidae birds (Rhea
americana [greater rhea] and R. pennata [lesser rhea]) and
bones and teeth from large, medium and small-sized mam-
mals, such as Lama guanicoe (guanaco), Chaetophractus
villosus (large hairy armadillo), Leopardus geoffroyi
(Geoffroy’s cat), Lycalopex griseus (grey fox or chilla),
Galictis cuja (lesser grison), Conepatus chinga (Molina’s
hog-nosed skunk), Microcavia australis (southern moun-
ta in cavy) and numerous s igmodont ine rodents
(Fernández et al. 2016).

Nine coprolites collected from unit II from ECh (1980 ± 80
to 1740 ± 60 years14C B.P.) were examined for parasites. The
coprolites were described, measured and weighted. The small-
er samples were whole processed by rehydration in a 0.5 %
water solution of trissodium phosphate (TSP) in a glass tube
for at least 72 h, followed by homogenization, filtered and
processed by spontaneous sedimentation (Lutz 1919). In the
case of bigger samples, 0.5 g from the surface and the interior
of coprolites was rehydrated. Samples were preserved in 70%
ethanol. Twenty slides of each sample were made with the aid
of a drop of sediment mixed with one drop of glycerin and
examined at 100× and 400× using a light microscopy. The

Fig. 1 Map of the archaeological
site Epullán Chica cave,
northwestern Patagonia,
Argentina

Archaeol Anthropol Sci



measurements are based on those taken from well-preserved
eggs. Egg dimensions and morphologies were compared with
data from the literature in order to identify the parasites at the
lowest taxonomic level. The macroscopic remains were sepa-
rated and dried at room temperature and were examined for
diet analysis.

Results

Table 1 presents measurements, microscopic and macroscopic
remains and parasitological records of each coprolite.
Macroscopic remains found in coprolites were indicative of
an omnivorous diet. Coprolites number 1, 2 and 3 showed a
mixture of inclusions such as small bone fragments, diminutive
vertebrae and ribs, scales of reptiles, vegetal remains and chitin
of insects. Coprolites showed dark colouration; they were very
light and easily broken. Coprolites 4 to 9 were brown and
cylindrics. Macroscopic observation of coprolite 4 displays
light brown hairs, vegetal remains and fragments of insect exo-
skeletons. Coprolites 5 to 9 showed vegetal and insect remains.
Coprolite 7 also displays diatoms. After rehydration, all sam-
ples exhibited a dark colouration (typical of carnivore faecal
material) and the coprolite number 3 presented an intense smell.

Microscopic observations revealed that 6 coprolites exam-
ined contained parasite remains. At least representatives of 10
species of helminths were recovered. Helminth eggs of

nematodes, cestodes and acanthocephalans were found
(Table 1). In all cases, eggs were very well-preserved.

Two different nematodes were found in coprolite number 1
(internal and external samples). In one case, eggs were oval,
smooth, thick-shelled and embryonated. Their measurements
were 45.0 to 55.0 μm (48.69 ± 2.50.32; N = 22) in length and
32.5 to 37.5 μm (34.83 ± 1.71; N = 20) in width. The identity
of eggs was attributed to genus Physaloptera sp. (Molin 1860)
(Spirurida: Physalopteridae) (Fig. 2). The other eggs were
oblong and thin-shelled and were observed both as embryo-
nated or unembryonated. Egg measurements (N = 3) were
85.0 to 90.0 μm (87.48 ± 2.5) in length and 47.5 to 50.0 μm
(49.15 ± 1.44) in width. These eggs were attributed to
ancylostomids, probably Uncinaria sp. (Froelich 1789)
(Strongylida, Ancylostomatidae) (Fig. 3).

Three different parasite species were found in pellet number
2. Eggs identified as acanthocephalan (Archiacanthocephala,
Oligacanthorhynchidae), probably Prostenorchis sp.
(Travassos 1915), were brown-coloured and thick-shelled, with
four membranes. The outer membrane was thick, granular and
with hyaline poles; the inner membrane thin and the embryos
with hooks in one extremity (Fig. 4). Eggs were found in inter-
nal and external samples. Egg measurements (N = 18) ranged
from 90.0 to 100.0μm (96.20 ± 3.16) long and 47.5 to 57.5 μm
(50.38 ± 3.06) wide; they were found from both internal and
external samples.

Eggs comparable to a trematode were also found (internal
sample). Eggs were ovoid, brownish yellow, thick-shelled,

Table 1 Measurements,
microscopic and macroscopic
remains and parasitological
records of each coprolite

Coprolite no. Diameter (mm) Macroscopic and
microscopic remains

Parasite eggs

1 10.15 Bones (ribs, vertebrae), reptile scales,
arthropod chitin

Physaloptera sp.

Uncinaria sp.

2 12.89 Bones fragments, arthropod chitin,
vegetal tissues, reptile scales

Prostenorchis sp.

Paragonimus sp.

Ancylostoma, probably A. conepati

3 16.92 Arthropod chitin, vegetal tissues,
pollen grains,

Eucoleus, probably E. aerophilus

4 15.48 Arthropod chitin, vegetal tissues,
pollen grains

Negative

5 18.51 Arthropod chitin, vegetal tissues,
pollen grains

Trichostrongylus, probably
T. colubriformis

Physaloptera sp.

Ascarididae

6 14.14 Arthropod chitin, vegetal tissues,
pollen grains

Monoecocestus sp.

Physaloptera sp.

7 12.51 Arthropod chitin, vegetal tissues,
diatoms, pollen grains

Negative

8 16.92 Arthropod chitin, vegetal tissues,
pollen grains

Ascarididae

9 14.16 Arthropod chitin, vegetal tissues,
pollen grains

Negative

Archaeol Anthropol Sci



unembryonated and operculated (Fig. 5). The posterior end
was thickened. The average measurements of eggs were
80.82 ± 1.44 by 56.33 ± 7.64μm (N = 3). Eggs were attributed
to genus Paragonimus (Platyhelminthes: Trematoda) (Braun
1899). Two eggs of nematodes attributed to Ancylostoma
(Strongylida, Ancylostomatidae), probably A. conepati
(Solanet 1911), were also found in coprolite 2 (internal sam-
ple). Eggs were ovoid with a thin shell. Measurements were
75 by 42.5 μm (Fig. 6).

One egg compatible with the capillariid Eucoleus sp.
(Nematoda: Capillariidae) (Fig. 7), probably E. aerophilus,
was found in coprolite number 3 (internal sample). The sur-
face of the wall exhibited a network of ridges. Egg measure-
ments were 50.0 (without plugs) and 62.5 (with plugs) in
length and 27.5 in width respectively.

Coprolite number 5 harboured 5 nematode species.
Oblong, thick-shelled and embryonated eggs similar to that
of spirurid species were observed. Egg measurements
(N = 11) were 62.5 to 67.5 m (62.19 ± 3.25) in length and
42.5 to 57.5 μm (46.17 ± 4.52) in width. Eggs were probably
attributed to Physaloptera sp. (Fig. 8), but to another species
to that of coprolite 1.

Oblong and larvated eggs with a thin wall were also found.
Measurements (N = 3) were 112.5 to 115.0 μm (113.33 ± 1.44)
in length and 50 to 62.5 μm (57.24 ± 6.61) in width. Eggs were

compatible to strongylid eggs (Strongylida, Trichostrongyloidea)
(Fig. 9). Their morphology and measurements were similar to
those of Trichostrongylus, probably T. colubriformis. Hatched
larvae were observed.

Three morphotypes of nematode eggs possibly belonged to
the family Ascarididae were recorded. Eggs were in different
embryonic stages. In none of these cases was the diagnosis
possible. In one case, eggs were rounded withmamillated wall
and embryonated. The average measurements of eggs were
61.71 ± 7.49 by 47.88 ± 1.88 μm (N = 6) (Fig. 10). The other
ascaridid eggs were brown and ellipsoid, unembryonated. The
average measurements of eggs were 52.96 ± 2.30 by
37.97 ± 1.58 μm (N = 10) (Fig. 11). Rounded, embryonated,
translucid and mamillated eggs were also found. The average
measurements of eggs were 54.15 ± 1.44 by 51.57 ± 3.82 μm
(N = 3) (Fig. 12).

Coprolite number 6 displayed one egg of anoplocephalid
(Cestoda: Anoplocephalidae), with characteristics attributable
to genus Monoecocestus (Beddard 1893) (Fig. 13).
Measurements of the egg were 72.5 by 55 μm. Nematode
eggs, similar to those found in coprolite number 5, attributable
to Physaloptera sp., were also found. Egg measurements
(N = 6) were 55.0 to 62.5 μm (58.27 ± 3.03) in length and
45.0 to 47.5 μm (46.23 ± 1.37) in width.

Fig. 4 Eggs found from Epullán Chica cave, identified as
acanthocephalan (Archiacanthocephala, Oligacanthorhynchidae),
probably Prostenorchis sp. Bar = 20 μm

Fig. 3 Eggs found from Epullán Chica cave, attributed to ancylostomids,
probably Uncinaria sp. (Strongylida, Ancylostomatidae). Bar = 20 μm

Fig. 5 Eggs found from Epullán Chica cave, attributed to genus
Paragonimus (Platyhelminthes: Trematoda). Bar = 20 μm

Fig. 2 Eggs found from Epullán Chica cave, tentatively attributed to
genus Physaloptera sp. (Spirurida: Physalopteridae). Bar = 20 μm

Archaeol Anthropol Sci



Coprolite 9 contained ascaririd eggs (Nematoda:
Ascarididae). Eggs were rounded and embryonated, with
mamillated walls and similar to those found in coprolite 5
(Fig. 10). The average measurements of eggs were
60.56 ± 3.42 by 49.15 ± 2.51 μm (N = 19).

Discussion

Based on morphological features and diet, coprolites were
assigned as belonging to any representative from Order
Carnivora. The carnivore species currently living in the stud-
ied area are Lycalopex culpaeus (culpeo fox) and L. griseus
(Canidae), Leopardus colocolo (pampas cat), L. geoffroyi,
Puma concolor (puma) (Felidae), C. chinga (Mephitidae),
G. cuja and Lyncodon patagonicus (Patagonian weasel)
(Mustelidae) (Barquez et al. 2006). Several bones of them,
including the four aforementioned families, were identified
in ECh (see BMaterial and Methods^ section).

The faeces of carnivores are characterized by their cylin-
drical shape, with subdivisions and tappered at one of the
extremities (Chame 2003). However, in C. chinga, these sub-
divisions are not easy to distinguish (Medina et al. 2009).
Hog-nosed skunks (Conepatus) are carnivores widely distrib-
uted, ranging from Texas to the outhernmost areas of South

America. The skunk C. chinga is a mephitid whose distribu-
tion ranges from northeastern Perú to southern Chile and to
certain areas of Bolivia, Paraguay, Uruguay, Argentina and
Brazil. Studies on the feeding habits of C. chinga suggest a
generalist consumer character, in which arthropods are the
most frequent prey, although small mammals are also a sub-
stantial part of its diet (Castillo et al. 2014; Donadío et al.
2004; Medina et al. 2009). Other preys include annelids, am-
phibians, reptiles and carrions. Themorphology, diet andmea-
surements of the examined coprolites 1, 2 and 3 were similar
to those of C. chinga.

Faeces 4 to 9 exhibited the typical carnivore characteristics.
Their measures and morphology correspond to those of a
small canid or feline. However, the diets of Felidae tend to
be more specific than those of other Carnivora, generally
consisting of mammalian prey of sizes commensurate with
their own body size, with little or no fish, vegetation or inver-
tebrates (Kruuk 1986; Walker et al. 2007). In general, foxes
tend to be omnivorous and opportunistic. The grey fox is both
diurnal and nocturnal and occurs in a broad range of habitats
from grasslands to forests, although in Argentina, it typically
inhabits arid and semiarid temperate portions of Patagonia and
the Andes. L. griseus is a generalist omnivore. The diet may
contain plant material, insects, birds, rodents, lizards and even
a high amount of fruit (Núñez and Bozzolo 2006; Zapata et al.
2005).Measurements of studied coprolites were similar to that

Fig. 7 Egg found from Epullán Chica cave, compatible with the
capillariid Eucoleus sp. (Nematoda: Capillariidae), probably
E. aerophilus. Bar = 20 μm

Fig. 9 Eggs found from Epullán Chica cave, compatible to
Trichostrongylus sp. (Strongylida, Trichostrongyloidea). Bar = 40 μm

Fig. 6 Eggs found from Epullán Chica cave, attributed to Ancylostoma
(Strongylida, Ancylostomatidae). Bar = 20 μm

Fig. 8 Eggs found from Epullán Chica cave were probably attributed to
Physaloptera sp. (Spirurida: Physalopteridae). Bar = 20 μm

Archaeol Anthropol Sci



of L. griseus. L. culpaeus has a narrower diet than L. griseus,
being exclusively carnivorous and their faeces are bigger
(Zapata et al. 2005).

Little is known about the parasite fauna of C. chinga.
Spirometra erinacei and Atriotaenia sanmarci (cestodes) and
A. conepati, Physaloptera cahuide and Physaloptera
maxillaris (nematodes) were reported (Gomez-Puerta et al.
2009, 2012; Sarmiento et al. 1999; Stein et al. 1994; Vega
et al. 2014; Vieira et al. 2008).

Species of Physaloptera are parasitic nematodes with the
adult stages living in the digestive tract of amphibians (3 spe-
cies), reptiles (45 species), birds (24 species) and mammals
(over 90 species) and more than 82 cases were described from
humans (Mohamadain and Ammar 2012). Their life cycle
includes intermediate hosts (orthopterans and coleopterans)
or paratenic hosts that harbour larval forms in the outer intes-
tinal wall (Quadros et al. 2014). Domestic and wild carnivores
(cougar, lynx, badger, raccoon, fox, striped hog-nosed skunk
and coyote) may be infected after eating arthropods containing
third-stage larvae. The development into the adult form takes
place in the definitive host and the worms lodge, preferably in
the oesophagus, in the gastric mucosa and in the small intes-
tine (Ortlepp 1922). Frequent movement of these nematodes
results in erosions and ulcers in the gastrointestinal tract
(Naem and Asadi 2013). Physaloptera maxillaris was the
most common helminth reported from striped skunks

(Mephitis mephitis) from USA (Dyer 1970; Lincoln and
Anderson 1972) and from hog-nosed skunks (Conepatus
leuconotus), striped skunks (M. mephitis) and spotted skunks
(Spilogale gracilis) from an area of sympatry from Texas
(Neiswenter et al. 2006). Humans on rare occasions have been
infected with this parasite. Physalopterawas identified in oth-
er prehistoric coprolites, which belonged to a canid (Fugassa
et al. 2006), to a prehistoric human from Patagonia, Argentina
(Fugassa et al. 2007) and to a human from the BLa Cueva de
los Muertos Chiquitos^ archaeological site, México (Cleeland
et al. 2013).

Paragonimus species are extremely successful parasites
with more than 40 species described (Blair et al. 2005).
Paragonimus spp. exhibit a complex life cycle that includes
a mammal as the definitive host and snails and crustaceans as
intermediate hosts (crabs and crayfish). Definitive hosts usu-
ally become infected by eating raw or undercooked tissues
from crustaceans. Paragonimiasis is a disease of humans and
other mammals caused by several species of Paragonimus.
Symptoms and signs mimic those of tuberculosis (Diaz
2013; Procop 2009). Human infections are present in Africa,
Asia and America, including USA, Mexico, Costa Rica,
Guatemala, Honduras, Nicaragua, Panamá, Colombia, Perú,
Venezuela and Brazil (Acha and Szyfres 2003). Paragonimus

Fig. 13 Anoplocephalid egg (Cestoda: Anoplocephalidae) found from
Epullán Chica cave, with characteristics attributable to genus
Monoecocestus. Bar = 20 μm

Fig. 10 Eggs found from Epullán Chica cave, belonged to the family
Ascarididae. Bar = 20 μm

Fig. 12 Eggs found from Epullán Chica cave, belonged to the family
Ascarididae. Bar = 20 μm

Fig. 11 Eggs found from Epullán Chica cave, possibly belonging to the
family Ascarididae. Bar = 20 μm

Archaeol Anthropol Sci



has not been reported from Argentina. There is only one pre-
vious palaeoparasitological record by Hall (1976) (in Horne
1985), who reported eggs of Paragonimus, from human cop-
rolites from the Atacama Desert of northern Chile dated to
5900 B.P. Exoskeletal fragments of freshwater crayfish or
shrimp were found in the same coprolites. Eggs were found
in a coprolite probably assigned to the skunk. Presidente and
Ramsden (1975) found P. kellicotti infection in striped skunks
(M. mephitis) and also in minks (Mustela vison), red foxes
(Vulpes vulpes) and coyotes (Canis latrans).

Individuals belong to the phylum Acanthocephala are ex-
clusively parasitic, including approximately 1150 described
species with indirect life cycles, always involving arthropods
as intermediate hosts and vertebrates as definitive hosts
(Kennedy 2006). A main characteristic of the phylum is a
protrusible proboscis armed with recurved hooks. Worms are
attached to the intestine walls of the definitive host. The fam-
ily Oligacanthorhynchidae includes 12 genera (Amin 2013).
One of them, Prosthenorchis, has been reported from South
America, as P. elegans from primates and P. cerdocyonis from
the crab-eating foxCerdocyon thous; fromAfrica, as P. lemuri
from lemurs in Madagascar, P. pardalis from Felis pardus in
Sierra Leone and P. fraterna from felid Panthera pardus in
Congo; and from Asia as P. sinicus, from a dog in China
(Amin 2013; Gomes et al. 2015). Eggs identified as
Macracanthorhynchus sp. or an unidentified species were
found in raptor pellets from the same layer of ECh
(Beltrame et al. 2015). There is scarce information of
Oligacanthorhynchids from South America. Although very
rare, acantocephalan human infection does occur. The earliest
discovery of infection was from the coprolite of a prehistoric
man in Utah with a significant number of Moniliformis eggs
(Moore et al. 1969). The finds of acanthocephalans from
North American archaeological sites were summarized by
Fugassa et al. 2011. Most patients with acanthocephalan in-
fection remain asymptomatic, but others experience abdomi-
nal pain, diarrea and anorexia with weight loss (Andres et al.
2014; Salehabodi et al. 2008).

Paras i tes of the superfamil ies St rongyloidea ,
Trichostrongyloidea and Ancylostomatoidea are nowadays of
major importance in human and veterinary medicine. The
strongylid species found in carnivores belong to the suborder
Strongylida (Ancylostomatidae) (Anderson et al. 2009). The
most common species found are Ancylostoma spp. and
Uncinaria spp. The life cycle of these hookworms begins with
the larvae hatching from eggs that passed in the host’s faeces,
developing to the infective stage (filariform larva) in soil and
accessing to the definitive host through skin penetration or via
ingestion. Infective larvae can also establish infections if
ingested. Larvae that penetrate the skin travel through various
organs, including the respiratory tract, before entering the intes-
tines and developing into mature hookworms. Hookworms can
cause anaemia, abdominal pain and diarrhoea when they reside

in the intestines or lungs with dermatologic and other signs
during their migration through the body (Bowman et al. 2010;
Traversa et al. 2014). Zoonotic hookworms in humans may
cause different pictures of skin, enteric and pulmonary diseases,
the cutaneous larva migrans being the most important.

From South America, Ancylostoma andUncinaria are usu-
ally found in several species of domestic carnivorous as dogs
and cats, as well as wild carnivorous as Darwin’s fox
(Lycalopex fulvipes) from Chile (Jiménez et al. 2012),
L. griseus from Argentina (Zanini et al. 2006), L. geoffroyi
from Argentina (Beldoménico et al. 2005), stray cat (Felis
catus) from Brazil (Uchôa et al. 1998) and A. braziliense
and P. concolor from Brazil. U. stenocephala was found in
L. culpaeus from Tierra del Fuego, Argentina (Aguilera
2001), from the Magellanic and Artic regions of Chile
(Alarcón Navarro 2005) and from Perú (Moro et al. 1998).
Ancylostoma conepati was found in C. chinga from Perú and
Brazil (Sarmiento et al. 1999; Vieira et al. 2008) and from
Chubut Province, Argentina (Vega et al. 2014).

Trichostrongylus spp. are primarily parasites of herbivores
with a worldwide distribution. Human infections are found
mainly in warm areas. T. colubriformis adults live in the in-
testines of the host. The female lays eggs with faeces. Eggs
hatch and mature into infectious larvae. Humans become in-
fected, ingesting unwashed vegetables contaminated by ani-
mal faeces or contaminated water containing strongyloid lar-
vae. Larvae mature into adults in the intestines. The zoonotic
tricostrongylosis is produced by several species of
Trichostrongylus. Sporadic cases of T. colubriformis in
humans have been reported (Lattès et al. 2011; Sato et al.
2011). Their presence in carnivores is accidental.
T. colubriformis was also found in L. griseus from Chile
(Alarcón Navarro 2005).

Another nematode frequently associated to wildlife is
E. aerophilus (syn. Capillaria aerophila). It is a trichuroid
nematode affecting the respiratory system of dogs, cats, wild
carnivores and occasionally humans (Traversa et al. 2011).
Adult stages live embedded underneath the epithelium of tra-
chea, bronchi and bronchioles of the infected host. Females
produce non-larvated eggs, which are coughed up and
swallowed, reaching the environment via the faeces, where
eggs mature. Eggs may also mature within earthworms (fac-
ultative intermediate hosts). Animals become infected by
ingesting the larvated eggs or, rarely, the invertebrates. After
ingestion, eggs hatch; larvae penetrate the intestinal wall and
migrate via the bloodstream to the lungs and moult and reach
their sexual maturity after 3 to 6 weeks post-infection
(Anderson 2000; Traversa et al. 2011). Clinical signs include
coughing and sneezing and in severe cases cause chronic re-
spiratory disease. E. aerophilus can infect humans, causing
bronchitis, coughing, mucoid sputum, blood in the mucous,
fever, dyspnea and pulmonary carcinoma-like masses
(Lalosević et al. 2008).

Archaeol Anthropol Sci



Previous studies on carnivores from Patagonia (Argentina
and Chile) stated that ascaririd species found were Toxocara
spp. and Toxascaris leonina (Aguilera 2001; Alarcón Navarro
2005; Jiménez et al. 2012; Sánchez Thevenet et al. 2003; Stein
et al. 1994; Zanini et al. 2006). Species belong to genus
Toxocara and Toxascaris which are zoonotic. Toxocarosis is
a major helminth zoonosis. These parasites have an oral–fae-
cal transmission cycle, and humans can be infected by inges-
tion of larvae in undercooked infected organ or muscle tissues
(rare); infective eggs from contaminated soil (gardens, sand-
pits and playgrounds); from unwashed hands or raw vegeta-
bles or by direct contact with pets (Overgaauw and van
Knapen 2013). A number of different syndromes have been
attributed to Toxocara spp. and Toxascaris spp. infection: vis-
ceral larva migrans (VLM), ocular larva migrans (OLM) and
covert toxocarosis (CT). In addition, associations with neuro-
logical and atopic symptoms have also been described.

The study of parasites in animal coprolites has developed
over the past decades worldwide. However, few studies have
been published on the parasites found in carnivore coprolites.
There are only two previous palaeoparasitological studies on
carnivores from Patagonia. Fugassa et al. (2006) examined
one canid coprolite dated at 6540 ± 110 B.P. probably belong-
ing to L. culpaeus collected from the Perito Moreno National
Park, Santa Cruz, Argentina. Eggs of nematodes identified as
Trichuris spp., Capillaria spp.,Uncinaria sp. and an ascaridid
(probably Toxascaris sp.) or spirurids (presumably
Physaloptera sp.), and one cestode (Anoplocephalidae), pre-
sumably Moniezia sp., were found. The second study exam-
ined feline coprolites from Perito Moreno National Park,
Santa Cruz Province, Argentina. Eggs compatible to
Trichuris sp., Calodium sp., Eucoleus sp., Nematodirus sp.,
Oesophagostomum sp. (Nematoda), Monoecocestus sp.
(Cestoda) and Eimeria macusaniensis (Coccidia) were recov-
ered (Fugassa et al. 2009).

The main faunal resources exploited by humans from ECh
were L. guanicoe, C. villosus and eggs of Rheidae. Carnivores
also seem to have been an occasional resource, possibly not
only for nutrients (e.g. defleshing marks in Lycalopex sp. and
G. cuja) but also for skins, as evidenced by skinning marks in
the mandible of L. geoffroyi. In addition, evidences of
L. griseus died naturally in situ were found, reinforcing the
idea of the use of the cave as a shelter by carnivores
(Fernández et al. 2016). Zooarchaeological studies of
Epullán Grande revealed a human subsistence similar to that
recorded in ECh, mostly focussed on the consumption of
large-sized mammals (L. guanicoe), and an increase through
time of a complementary source of food integrated by large-
sized birds (R. pennata) and medium-sized (L. griseus and
L. culpaeus, C. chinga and C. villosus) and micro-sized mam-
mals (the tuco-tucos Ctenomys spp., and the cavies
G. leucoblephara and M. australis) (Cordero 2009; Crivelli
Montero et al. 1996). These evidences show the close

interaction of human with carnivores and therefore the expo-
sition to the zoonoses previously mentioned.

Zooarchaeological evidence from ECh also includes fresh-
water mollusc shells (D. chilensis) reflecting that the freshwa-
ter ecosystemswere part of the subsistence patterns of the Late
Holocene hunter-gatherers of the middle Limay River basin
(Fernández et al. 2016). Hunther-gatherers from ECh could be
infected by Paragonimus if they have the practice of hunting
crustaceans in the close rivers.

There are ∼1400 known species of human pathogens, in-
cluding viruses, bacteria, fungi, protozoa and helminths
(Taylor et al. 2001). Of these, 65 % are zoonotic and 177
species are responsible for emerging infectious diseases
(Dutour 2013). Results displayed in the present study are in
line with the reconstruction of the scenario of zoonoses in the
past and the diseases that the human populations and animals
from Patagonia could be exposed. The present study consti-
tutes the first palaeoparasitological report of carnivore copro-
lites recovered from the archaeological site ECh and reflects
contamination of the cave used by hunter-gatherers with dif-
ferent parasites causative of zoonotic diseases.

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Archaeol Anthropol Sci


	Carnivores...
	Abstract
	Introduction
	Material and methods
	Results
	Discussion
	References